OOPSE-4/forceFields/MnM.frc

// This is the forcefield file for the Metal-NonMetal(MnM) Interaction Forcefield
//
// The sections are divided into AtomTypes
//


begin Options
      Name                   = "MnM"
          MetallicEnergyUnitScaling   23.0605423
end Options

begin AtomTypes    
//Name          mass     (amu)
CH4             16.05           
CH3             15.04           
CH2             14.03           
CH              13.02   
SSD             18.0153         
SSD1            18.0153 
SSD_E           18.0153
SSD_RF          18.0153                 
O_TIP3P         15.9994                 
O_TIP4P         15.9994
O_TIP4P-Ew      15.9994
O_TIP5P         15.9994 
O_TIP5P-E       15.9994 
O_SPCE          15.9994
O_SPC           15.9994 
H_TIP3P         1.0079
H_TIP4P         1.0079
H_TIP4P-Ew      1.0079
H_TIP5P         1.0079
H_SPCE          1.0079
H_SPC           1.0079
EP_TIP4P        0.0
EP_TIP4P-Ew     0.0
EP_TIP5P        0.0
C               12.0107
S       32.0655 
Ni      58.710
Cu      63.550
Rh      102.90550
Pd      106.42
Ag      107.8682
Ir      192.217
Pt      195.09
Au      196.97
end AtomTypes

begin DirectionalAtomTypes
//Name          I_xx    I_yy    I_zz    (All moments in (amu*Ang^2)
SSD             1.7696  0.6145  1.1550  
SSD1            1.7696  0.6145  1.1550  
SSD_E           1.7696  0.6145  1.1550  
SSD_RF          1.7696  0.6145  1.1550  
end DirectionalAtomTypes                    


begin LennardJonesAtomTypes
//Name          epsilon             sigma       
SSD             0.152           3.051                                   
SSD1            0.152           3.016 
SSD_E           0.152           3.035
SSD_RF          0.152           3.019
O_TIP3P         0.1521          3.15061 
O_TIP4P         0.1550          3.15365 
O_TIP4P-Ew      0.16275         3.16435
O_TIP5P         0.16            3.12   
O_TIP5P-E       0.178           3.097   
O_SPCE          0.15532         3.16549
O_SPC           0.15532         3.16549
CH4             0.279           3.73
CH3             0.185           3.75
CH2             0.0866          3.95
CH              0.0189          4.68
C               0.101745452544  3.35
end LennardJonesAtomTypes

begin SCAtomTypes
// Name  epsilon(eV)      c      m       n      alpha(angstroms)
Ni      0.0073767       84.745  5.0     10.0    3.5157 
Cu      0.0057921       84.843  5.0     10.0    3.6030
Rh      0.0024612       305.499 5.0     13.0    3.7984
Pd      0.0032864       148.205 6.0     12.0    3.8813
Ag      0.0039450       96.524  6.0     11.0    4.0691
Ir      0.0037674       224.815 6.0     13.0    3.8344  
Pt      0.0097894       71.336  7.0     11.0    3.9163
Au      0.0078052       53.581  8.0     11.0    4.0651
end SCAtomTypes


// Metal non-metal interactions.
// Format: Metal Atom Type, Non-Metal Atom Type, Interaction Type, Interaction Parameters
// Where interaction type can be: MAW, LennardJones or ShiftedMorse or RepulsiveMorse
begin MetalNonMetalInteractions

//MAW (Metal Angular Water section)
// r0, D0 beta0 betaH gamma alpha
Cu   SSD  MAW  2.5525 1.9850 1.1680  1.0500 0.2234 1.1250
Au   SSD  MAW  2.8170 1.7850 1.2680  1.2500 0.2050 1.0250

//LennardJones
// sigma epsilon


//Shifted Morse
// r0 D0 beta0
Au O_SPCE  3.70 0.0424 0.769

//Repulsive Morse
// r0 D0 beta0
Au H_SPCE -1.00 0.00850 0.769


end MetalNonMetalInteractions


begin ChargeAtomTypes
// Name         charge
O_TIP3P         -0.834
O_SPCE          -0.8476
O_SPC           -0.82
H_TIP3P         0.417
H_TIP4P         0.520
H_TIP4P-Ew      0.52422
H_TIP5P         0.241
H_SPCE          0.4238
H_SPC           0.42
EP_TIP4P        -1.040
EP_TIP4P-Ew     -1.04844
EP_TIP5P        -0.241
end ChargeAtomTypes

begin MultipoleAtomTypes
// OOPSE currently only supports charge-charge, charge-dipole, 
// dipole-dipole, and charge-quadrupole interactions.
// Dipoles may be either traditional point-dipoles or split-dipoles.
// possible formats for a multipolar atom type are:
//
// Point-dipoles:
// name d phi theta psi dipole_moment
//
// Split-dipoles:
// name s phi theta psi dipole_moment splitdipole_distance
//
// Point-Quadrupoles:
// name q phi theta psi Qxx Qyy Qzz
//
// Atoms with both dipole and quadrupole moments:
// name dq phi theta psi dipole_moment Qxx Qyy Qzz
//
// Atoms with both split dipoles and quadrupole moments:
// name sq phi theta psi dipole_moment splitdipole_distance Qxx Qyy Qzz
//
// Euler angles are given in zxz convention in units of degrees.
//
// Charges are given in units of electrons.
//
// Dipoles are given in units of Debyes.
//
// Split dipole distances are given in units of Angstroms.
//  
// Quadrupole moments are given in units of 10^-26 esu cm^2 (also known as an
//                                                           esu centi-barn)
//
SSD_E   dq      0.0     0.0     0.0     2.42    -1.682  1.762   -0.08
SSD_RF  dq      0.0     0.0     0.0     2.48    -1.682  1.762   -0.08
SSD     dq      0.0     0.0     0.0     2.35    -1.682  1.762   -0.08
SSD1    dq      0.0     0.0     0.0     2.35    -1.682  1.762   -0.08
end MultipoleAtomTypes

begin StickyAtomTypes
//name  w0      v0 (kcal/mol)   v0p     rl (Ang)  ru    rlp     rup
SSD_E   0.07715 3.90            3.90    2.40      3.80  2.75    3.35
SSD_RF  0.07715 3.90            3.90    2.40      3.80  2.75    3.35
SSD     0.07715 3.7284          3.7284  2.75      3.35  2.75    4.0
SSD1    0.07715 3.6613          3.6613  2.75      3.35  2.75    4.0
end StickyAtomTypes


begin BondTypes

//Atom1 Atom2   Fixed
//V_Fixed = 0

//Atom1 Atom2   Harmonic        b0              Kb (kcal/mol)
//V_Harmonic = 0.5*Kb(b- bo)^2
//Harmonic Examples
CH3         CH3 Harmonic                1.526           260
CH3         CH2 Harmonic                1.526           260
CH3         CH  Harmonic                1.526           260
CH2         CH2 Harmonic                1.526           260
CH2         CH  Harmonic                1.526           260
CH          CH  Harmonic                1.526           260

//Atom1 Atom2   Cubic           b0      K3      K2      K1      K0
//V_Cubic = K3(b - b0)^3 + K2(b - b0)^2 + K1(b - b0) + K0


//Atom1 Atom2   Quartic b0      K4      K3      K2      K1      K0
//V_Quartic = K4(b - b0)^4 + K3(b - b0)^3 + K2(b - b0)^2 + K1(b - b0) + K0


//Atom1 Atom2   Polynomial      b0      i       Ki      [j      Kj]
//V_Quartic = Ki(b - b0)^i + Kj(b - b0)^j + ...


end BondTypes

begin BendTypes

//Harmonic
//Atom1 Atom2   Atom3   Harmonic        Theta0  Ktheta
//V_Harmonic = 0.5*Ktheta(Theta - Theta0)^2
//Ktheta: kcal/mole/rad**2
//Theta0: degrees
//Harmonic examples
//
CH3     CH2     CH3     Harmonic        114.0   117.68
CH3     CH2     CH2     Harmonic        114.0   117.68
CH3     CH2     CH      Harmonic        114.0   117.68
CH3     CH      CH3     Harmonic        112.0   117.68
CH3     CH      CH2     Harmonic        112.0   117.68
CH3     CH      CH      Harmonic        112.0   117.68
CH2     CH2     CH2     Harmonic        114.0   117.68
CH2     CH2     CH      Harmonic        114.0   117.68
CH2     CH      CH2     Harmonic        112.0   117.68
CH2     CH      CH      Harmonic        112.0   117.68
CH      CH2     CH      Harmonic        114.0   117.68
CH      CH      CH      Harmonic        112.0   117.68


//UreyBradley
//Atom1 Atom2   Atom3   UreyBradley             Theta0  Ktheta  S0      Kub
//V_UreyBradleyBend = Ktheta(Theta - Theta0)^2 +  Kub(S - S0)^2
//Ktheta: kcal/mole/rad**2
//Theta0: degrees
//Kub: kcal/mole/A**2
//S0: A

//Cubic
//Atom1 Atom2   Atom3   Cubic   Theta0  K3      K2      K1      K0
//V_Cubic = K3(Theta - Theta0)^3 + K2(Theta - Theta0)^2 + K1(Theta - Theta0) + K0

//Quartic
//Atom1 Atom2   Atom3   Quartic Theta0  K4      K3      K2      K1      K0
//V_Quartic = K4(Theta - Theta0)^4 + K3(Theta - Theta0)^3 + K2(Theta - Theta0)^2 + K1(Theta - Theta0) + K0

//Polynomial
//Atom1 Atom2   Atom3   Polynomial      Theta0  i       Ki      [j      Kj]
//V_Polynomial = Ki(Theta - Theta0)^i +  Kj(Theta - Theta0)^j + ...

end BendTypes

begin TorsionTypes

//Cubic
//Atom1 Atom2   Atom3   Atom4   Cubic           k3              k2              k1              k0  ( all are kcal/mol )
//V_Cubic = k3(cos phi)^3 + k2(cos phi)^2 + k1(cos phi) + k0
//Cubic Examples
CH3     CH2     CH2     CH3     Cubic           5.9602          -0.2568         -3.802          2.1586
CH3     CH2     CH      CH3     Cubic           3.3254          -0.4215         -1.686          1.1661
CH3     CH      CH      CH3     Cubic           3.3254          -0.4215         -1.686          1.1661
CH3     CH2     CH2     CH2     Cubic           5.9602          -0.2568         -3.802          2.1586
CH3     CH2     CH      CH2     Cubic           3.3254          -0.4215         -1.686          1.1661
CH3     CH      CH2     CH2     Cubic           3.3254          -0.4215         -1.686          1.1661
CH3     CH      CH      CH2     Cubic           3.3254          -0.4215         -1.686          1.1661
CH3     CH2     CH2     CH      Cubic           5.9602          -0.2568         -3.802          2.1586
CH3     CH2     CH      CH      Cubic           3.3254          -0.4215         -1.686          1.1661
CH3     CH      CH2     CH      Cubic           3.3254          -0.4215         -1.686          1.1661
CH3     CH      CH      CH      Cubic           3.3254          -0.4215         -1.686          1.1661
CH2     CH2     CH2     CH2     Cubic           5.9602          -0.2568         -3.802          2.1586
CH2     CH2     CH      CH2     Cubic           3.3254          -0.4215         -1.686          1.1661
CH2     CH      CH      CH2     Cubic           3.3254          -0.4215         -1.686          1.1661
CH2     CH2     CH2     CH      Cubic           5.9602          -0.2568         -3.802          2.1586
CH2     CH2     CH      CH      Cubic           3.3254          -0.4215         -1.686          1.1661
CH2     CH      CH2     CH      Cubic           3.3254          -0.4215         -1.686          1.1661
CH2     CH      CH      CH      Cubic           3.3254          -0.4215         -1.686          1.1661
CH      CH2     CH2     CH      Cubic           5.9602          -0.2568         -3.802          2.1586
CH      CH2     CH      CH      Cubic           3.3254          -0.4215         -1.686          1.1661
CH      CH      CH      CH      Cubic           3.3254          -0.4215         -1.686          1.1661


//Charmm
//Atom1 Atom2   Atom3   Atom4   Charmm          Kchi            n               delta           [Kchi           n               delta]
//V_Charmm =  Kchi(1 + cos(n(chi) - delta))
//Kchi: kcal/mole
//n: multiplicity
//delta: degrees
//in some cases, a Charmm may have two or three terms. If n is equal to 0, it falls back to harmonic form

//Quartic
//Atom1 Atom2   Atom3   Atom4   Quartic         k4              k3              k2              k1              k0  ( all are kcal/mol )
//V_Quartic = k4(cos phi)^4 + k3(cos phi)^3 + k2(cos phi)^2 + k1(cos phi) + k0

//Polynomial
//Atom1 Atom2   Atom3   Atom4   Polynomial      i       Ki      [j      Kj] 
//VPolynomial = Ki (cos phi)^i + ... + Kj (cos phi)^j

end TorsionTypes


Revision:	3161
Committed:	Thu Jul 12 23:19:16 2007 UTC (17 years ago) by chuckv
File size:	8600 byte(s)
Log Message:	Added metal-non-metal section
#	Content
1	// This is the forcefield file for the Metal-NonMetal(MnM) Interaction Forcefield
2	//
3	// The sections are divided into AtomTypes
4	//
5
6
7	begin Options
8	Name = "MnM"
9	MetallicEnergyUnitScaling 23.0605423
10	end Options
11
12	begin AtomTypes
13	//Name mass (amu)
14	CH4 16.05
15	CH3 15.04
16	CH2 14.03
17	CH 13.02
18	SSD 18.0153
19	SSD1 18.0153
20	SSD_E 18.0153
21	SSD_RF 18.0153
22	O_TIP3P 15.9994
23	O_TIP4P 15.9994
24	O_TIP4P-Ew 15.9994
25	O_TIP5P 15.9994
26	O_TIP5P-E 15.9994
27	O_SPCE 15.9994
28	O_SPC 15.9994
29	H_TIP3P 1.0079
30	H_TIP4P 1.0079
31	H_TIP4P-Ew 1.0079
32	H_TIP5P 1.0079
33	H_SPCE 1.0079
34	H_SPC 1.0079
35	EP_TIP4P 0.0
36	EP_TIP4P-Ew 0.0
37	EP_TIP5P 0.0
38	C 12.0107
39	S 32.0655
40	Ni 58.710
41	Cu 63.550
42	Rh 102.90550
43	Pd 106.42
44	Ag 107.8682
45	Ir 192.217
46	Pt 195.09
47	Au 196.97
48	end AtomTypes
49
50	begin DirectionalAtomTypes
51	//Name I_xx I_yy I_zz (All moments in (amu*Ang^2)
52	SSD 1.7696 0.6145 1.1550
53	SSD1 1.7696 0.6145 1.1550
54	SSD_E 1.7696 0.6145 1.1550
55	SSD_RF 1.7696 0.6145 1.1550
56	end DirectionalAtomTypes
57
58
59	begin LennardJonesAtomTypes
60	//Name epsilon sigma
61	SSD 0.152 3.051
62	SSD1 0.152 3.016
63	SSD_E 0.152 3.035
64	SSD_RF 0.152 3.019
65	O_TIP3P 0.1521 3.15061
66	O_TIP4P 0.1550 3.15365
67	O_TIP4P-Ew 0.16275 3.16435
68	O_TIP5P 0.16 3.12
69	O_TIP5P-E 0.178 3.097
70	O_SPCE 0.15532 3.16549
71	O_SPC 0.15532 3.16549
72	CH4 0.279 3.73
73	CH3 0.185 3.75
74	CH2 0.0866 3.95
75	CH 0.0189 4.68
76	C 0.101745452544 3.35
77	end LennardJonesAtomTypes
78
79	begin SCAtomTypes
80	// Name epsilon(eV) c m n alpha(angstroms)
81	Ni 0.0073767 84.745 5.0 10.0 3.5157
82	Cu 0.0057921 84.843 5.0 10.0 3.6030
83	Rh 0.0024612 305.499 5.0 13.0 3.7984
84	Pd 0.0032864 148.205 6.0 12.0 3.8813
85	Ag 0.0039450 96.524 6.0 11.0 4.0691
86	Ir 0.0037674 224.815 6.0 13.0 3.8344
87	Pt 0.0097894 71.336 7.0 11.0 3.9163
88	Au 0.0078052 53.581 8.0 11.0 4.0651
89	end SCAtomTypes
90
91
92	// Metal non-metal interactions.
93	// Format: Metal Atom Type, Non-Metal Atom Type, Interaction Type, Interaction Parameters
94	// Where interaction type can be: MAW, LennardJones or ShiftedMorse or RepulsiveMorse
95	begin MetalNonMetalInteractions
96
97	//MAW (Metal Angular Water section)
98	// r0, D0 beta0 betaH gamma alpha
99	Cu SSD MAW 2.5525 1.9850 1.1680 1.0500 0.2234 1.1250
100	Au SSD MAW 2.8170 1.7850 1.2680 1.2500 0.2050 1.0250
101
102	//LennardJones
103	// sigma epsilon
104
105
106	//Shifted Morse
107	// r0 D0 beta0
108	Au O_SPCE 3.70 0.0424 0.769
109
110	//Repulsive Morse
111	// r0 D0 beta0
112	Au H_SPCE -1.00 0.00850 0.769
113
114
115	end MetalNonMetalInteractions
116
117
118	begin ChargeAtomTypes
119	// Name charge
120	O_TIP3P -0.834
121	O_SPCE -0.8476
122	O_SPC -0.82
123	H_TIP3P 0.417
124	H_TIP4P 0.520
125	H_TIP4P-Ew 0.52422
126	H_TIP5P 0.241
127	H_SPCE 0.4238
128	H_SPC 0.42
129	EP_TIP4P -1.040
130	EP_TIP4P-Ew -1.04844
131	EP_TIP5P -0.241
132	end ChargeAtomTypes
133
134	begin MultipoleAtomTypes
135	// OOPSE currently only supports charge-charge, charge-dipole,
136	// dipole-dipole, and charge-quadrupole interactions.
137	// Dipoles may be either traditional point-dipoles or split-dipoles.
138	// possible formats for a multipolar atom type are:
139	//
140	// Point-dipoles:
141	// name d phi theta psi dipole_moment
142	//
143	// Split-dipoles:
144	// name s phi theta psi dipole_moment splitdipole_distance
145	//
146	// Point-Quadrupoles:
147	// name q phi theta psi Qxx Qyy Qzz
148	//
149	// Atoms with both dipole and quadrupole moments:
150	// name dq phi theta psi dipole_moment Qxx Qyy Qzz
151	//
152	// Atoms with both split dipoles and quadrupole moments:
153	// name sq phi theta psi dipole_moment splitdipole_distance Qxx Qyy Qzz
154	//
155	// Euler angles are given in zxz convention in units of degrees.
156	//
157	// Charges are given in units of electrons.
158	//
159	// Dipoles are given in units of Debyes.
160	//
161	// Split dipole distances are given in units of Angstroms.
162	//
163	// Quadrupole moments are given in units of 10^-26 esu cm^2 (also known as an
164	// esu centi-barn)
165	//
166	SSD_E dq 0.0 0.0 0.0 2.42 -1.682 1.762 -0.08
167	SSD_RF dq 0.0 0.0 0.0 2.48 -1.682 1.762 -0.08
168	SSD dq 0.0 0.0 0.0 2.35 -1.682 1.762 -0.08
169	SSD1 dq 0.0 0.0 0.0 2.35 -1.682 1.762 -0.08
170	end MultipoleAtomTypes
171
172	begin StickyAtomTypes
173	//name w0 v0 (kcal/mol) v0p rl (Ang) ru rlp rup
174	SSD_E 0.07715 3.90 3.90 2.40 3.80 2.75 3.35
175	SSD_RF 0.07715 3.90 3.90 2.40 3.80 2.75 3.35
176	SSD 0.07715 3.7284 3.7284 2.75 3.35 2.75 4.0
177	SSD1 0.07715 3.6613 3.6613 2.75 3.35 2.75 4.0
178	end StickyAtomTypes
179
180
181	begin BondTypes
182
183	//Atom1 Atom2 Fixed
184	//V_Fixed = 0
185
186	//Atom1 Atom2 Harmonic b0 Kb (kcal/mol)
187	//V_Harmonic = 0.5*Kb(b- bo)^2
188	//Harmonic Examples
189	CH3 CH3 Harmonic 1.526 260
190	CH3 CH2 Harmonic 1.526 260
191	CH3 CH Harmonic 1.526 260
192	CH2 CH2 Harmonic 1.526 260
193	CH2 CH Harmonic 1.526 260
194	CH CH Harmonic 1.526 260
195
196	//Atom1 Atom2 Cubic b0 K3 K2 K1 K0
197	//V_Cubic = K3(b - b0)^3 + K2(b - b0)^2 + K1(b - b0) + K0
198
199
200	//Atom1 Atom2 Quartic b0 K4 K3 K2 K1 K0
201	//V_Quartic = K4(b - b0)^4 + K3(b - b0)^3 + K2(b - b0)^2 + K1(b - b0) + K0
202
203
204	//Atom1 Atom2 Polynomial b0 i Ki [j Kj]
205	//V_Quartic = Ki(b - b0)^i + Kj(b - b0)^j + ...
206
207
208	end BondTypes
209
210	begin BendTypes
211
212	//Harmonic
213	//Atom1 Atom2 Atom3 Harmonic Theta0 Ktheta
214	//V_Harmonic = 0.5*Ktheta(Theta - Theta0)^2
215	//Ktheta: kcal/mole/rad**2
216	//Theta0: degrees
217	//Harmonic examples
218	//
219	CH3 CH2 CH3 Harmonic 114.0 117.68
220	CH3 CH2 CH2 Harmonic 114.0 117.68
221	CH3 CH2 CH Harmonic 114.0 117.68
222	CH3 CH CH3 Harmonic 112.0 117.68
223	CH3 CH CH2 Harmonic 112.0 117.68
224	CH3 CH CH Harmonic 112.0 117.68
225	CH2 CH2 CH2 Harmonic 114.0 117.68
226	CH2 CH2 CH Harmonic 114.0 117.68
227	CH2 CH CH2 Harmonic 112.0 117.68
228	CH2 CH CH Harmonic 112.0 117.68
229	CH CH2 CH Harmonic 114.0 117.68
230	CH CH CH Harmonic 112.0 117.68
231
232
233
234	//UreyBradley
235	//Atom1 Atom2 Atom3 UreyBradley Theta0 Ktheta S0 Kub
236	//V_UreyBradleyBend = Ktheta(Theta - Theta0)^2 + Kub(S - S0)^2
237	//Ktheta: kcal/mole/rad**2
238	//Theta0: degrees
239	//Kub: kcal/mole/A**2
240	//S0: A
241
242	//Cubic
243	//Atom1 Atom2 Atom3 Cubic Theta0 K3 K2 K1 K0
244	//V_Cubic = K3(Theta - Theta0)^3 + K2(Theta - Theta0)^2 + K1(Theta - Theta0) + K0
245
246	//Quartic
247	//Atom1 Atom2 Atom3 Quartic Theta0 K4 K3 K2 K1 K0
248	//V_Quartic = K4(Theta - Theta0)^4 + K3(Theta - Theta0)^3 + K2(Theta - Theta0)^2 + K1(Theta - Theta0) + K0
249
250	//Polynomial
251	//Atom1 Atom2 Atom3 Polynomial Theta0 i Ki [j Kj]
252	//V_Polynomial = Ki(Theta - Theta0)^i + Kj(Theta - Theta0)^j + ...
253
254	end BendTypes
255
256	begin TorsionTypes
257
258	//Cubic
259	//Atom1 Atom2 Atom3 Atom4 Cubic k3 k2 k1 k0 ( all are kcal/mol )
260	//V_Cubic = k3(cos phi)^3 + k2(cos phi)^2 + k1(cos phi) + k0
261	//Cubic Examples
262	CH3 CH2 CH2 CH3 Cubic 5.9602 -0.2568 -3.802 2.1586
263	CH3 CH2 CH CH3 Cubic 3.3254 -0.4215 -1.686 1.1661
264	CH3 CH CH CH3 Cubic 3.3254 -0.4215 -1.686 1.1661
265	CH3 CH2 CH2 CH2 Cubic 5.9602 -0.2568 -3.802 2.1586
266	CH3 CH2 CH CH2 Cubic 3.3254 -0.4215 -1.686 1.1661
267	CH3 CH CH2 CH2 Cubic 3.3254 -0.4215 -1.686 1.1661
268	CH3 CH CH CH2 Cubic 3.3254 -0.4215 -1.686 1.1661
269	CH3 CH2 CH2 CH Cubic 5.9602 -0.2568 -3.802 2.1586
270	CH3 CH2 CH CH Cubic 3.3254 -0.4215 -1.686 1.1661
271	CH3 CH CH2 CH Cubic 3.3254 -0.4215 -1.686 1.1661
272	CH3 CH CH CH Cubic 3.3254 -0.4215 -1.686 1.1661
273	CH2 CH2 CH2 CH2 Cubic 5.9602 -0.2568 -3.802 2.1586
274	CH2 CH2 CH CH2 Cubic 3.3254 -0.4215 -1.686 1.1661
275	CH2 CH CH CH2 Cubic 3.3254 -0.4215 -1.686 1.1661
276	CH2 CH2 CH2 CH Cubic 5.9602 -0.2568 -3.802 2.1586
277	CH2 CH2 CH CH Cubic 3.3254 -0.4215 -1.686 1.1661
278	CH2 CH CH2 CH Cubic 3.3254 -0.4215 -1.686 1.1661
279	CH2 CH CH CH Cubic 3.3254 -0.4215 -1.686 1.1661
280	CH CH2 CH2 CH Cubic 5.9602 -0.2568 -3.802 2.1586
281	CH CH2 CH CH Cubic 3.3254 -0.4215 -1.686 1.1661
282	CH CH CH CH Cubic 3.3254 -0.4215 -1.686 1.1661
283
284
285	//Charmm
286	//Atom1 Atom2 Atom3 Atom4 Charmm Kchi n delta [Kchi n delta]
287	//V_Charmm = Kchi(1 + cos(n(chi) - delta))
288	//Kchi: kcal/mole
289	//n: multiplicity
290	//delta: degrees
291	//in some cases, a Charmm may have two or three terms. If n is equal to 0, it falls back to harmonic form
292
293	//Quartic
294	//Atom1 Atom2 Atom3 Atom4 Quartic k4 k3 k2 k1 k0 ( all are kcal/mol )
295	//V_Quartic = k4(cos phi)^4 + k3(cos phi)^3 + k2(cos phi)^2 + k1(cos phi) + k0
296
297	//Polynomial
298	//Atom1 Atom2 Atom3 Atom4 Polynomial i Ki [j Kj]
299	//VPolynomial = Ki (cos phi)^i + ... + Kj (cos phi)^j
300
301	end TorsionTypes
302
303